Mise au point de micelles polymères pour la formulation d'agents anticancéreux hydrophobes

Le Garrec, Dorothée

January 2006

Thèse numérisée par la Direction des bibliothèques de l'Université de Montréal.

Micelles polymères

Poly(N-isopropylacrylamide)

Acide lactique

Sensible au pH

Médicaments anticancéreux

Microgéis termo-responsivos preparados a partir dos polímeros do amido

Leite, Daiani Canabarro

January 2017

Esta tese apresenta os estudos realizados quanto à síntese e caracterização de microgéis termo-responsivos de N-isopropilacrilamida (NIPAM) e macromoléculas de origem amilácea em sua composição, sistemas ainda pouco explorados na literatura. Inicialmente, nanopartículas de amido (SNP) foram preparadas por nanoprecipitação para incorporação nos microgéis de interesse, através da dissolução dos grânulos do amido em DMSO/H2O, aplicação de ultrassom e precipitação em não-solvente. As SNPs preparadas foram utilizadas como copolímero para formação de microgéis híbridos do tipo SNP-co-p(NIPAM) através de polimerização em emulsão na presença e na ausência de surfactante. A influência das SNPs nas propriedades dos microgéis foi estudada por MEV, DLS, PZ e SAXS, onde foram observadas mudanças no comportamento físico-químico e estrutura supramolecular dos microgéis. No geral, observaram-se deslocamentos da temperatura de transição de fase para valores maiores (até 35 °C, cerca de 3 °C acima do valor determinado para sistemas contendo p(NIPAM) puro), aumento da estabilidade coloidal e organização dos polímeros presentes no microgel em uma arquitetura caroço-casca. As propriedades de inchamento dos microgéis também foram estudadas através da teoria de Flory-Rehner, onde a temperatura theta e o grau de polimerização entre dois pontos de reticulação foram determinados através do ajuste apropriado do parâmetro de interação (χ). Paralelamente, visando um sistema diferente do descrito acima, foi estudado um novo agente de reticulação baseado nos polímeros do amido, a amilose e a amilopectina. Para isso, os polímeros do amido que compõem as nanopartículas foram modificados para a utilização como agente de reticulação na síntese de microgéis de p(NIPAM). Nesta etapa, uma reação de substituição dos grupos hidroxila dos polímeros do amido foi realizada com o cloreto de acriloíla de forma a inserir insaturações na estrutura dos polímeros, para que estes fossem aplicados como reticulante. O sucesso da reação de modificação foi verificado através de RMN 1H e FTIR, no qual um maior grau de substituição foi obtido quando um tempo maior de reação foi empregado. Microgéis de p(NIPAM) foram então preparados através de polimerização em emulsão utilizando os reticulantes sintetizados. Observou-se a influência do grau de substituição e da concentração do reticulante nos microgéis, analisados por MEV, DLS e UV-Vis com controle de temperatura. As principais mudanças foram relativas à temperatura de transição de fase e tamanho dos microgéis. Utilizando o agente de reticulação com maior grau de substituição, foi possível deslocar a temperatura de transição de fase dos microgéis preparados para valores maiores (35 °C, cerca de 3 °C acima do valor determinado para sistemas contendo p(NIPAM) puro). Observou-se também uma resposta mecânica da rede do microgel, que refletiu no tamanho das partículas, influenciada pela concentração dos agentes de reticulação e do grau de substituição. Quanto maior a concentração e o grau de substituição do agente de reticulação, maior a resistência ao intumescimento observado no microgel. / This thesis presents the studies regarding the synthesis and characterization of thermoresponsive microgels of N-isopropylacrylamide (NIPAM) and amylaceous-based macromolecules, which are systems still little explored in the literature. At first, starch nanoparticles (SNP) were prepared by nanoprecipitation, through dissolution of starch granules in DMSO/H2O, ultrasound application and non-solvent precipitation. SNPs were then used as copolymer in SNP-co-p(NIPAM) hybrid microgels synthesized by emulsion polymerization in the presence and absence of surfactant. The influence of SNPs in microgel properties were studied by SEM, DLS, ZP, and SAXS, where changes in the physicalchemical behavior and supramolecular structure were observed. Summing up, shifts in the phase transition temperature up to 35 °C, increased colloidal stability, and microgel polymers organization into a core-shell structure were observed. Microgels swelling behaviour were also studied by the Flory-Rehner theory, where the theta-temperature and the degree of polymerization between two crosslinker points were determined through interaction parameter (χ) fitting. In parallel, a new starch-based crosslinker was studied. For this purpose, starch polymers (amylose and amylopectin within the SNPs) were modified in order to use them as crosslinker in p(NIPAM) microgel synthesis. In this step, a substitution reaction in hydroxyl groups of SNP was carried out with acryloyl chloride, where double bonds were attached in polymers structure, making it suitable as a crosslinker. Reaction performances were evaluated through 1H NMR and FTIR. Then, p(NIPAM) microgels were prepared by emulsion polymerization using the crosslinker synthesized. The degree of substitution and the crosslinker concentration influence were verified and analyzed by SEM, DLS and UV-Vis with temperature control. The main observed changes were related to the phase transition temperature e microgels size. Using the crosslinker with higher substitution degree, it was possible the shift of the phase transition temperature to higher values (~35 °C). A mechanical response, observed trough microgels size, was found, driven by the crosslinker concentration and substitution degree. As higher the concentration and substitution degree of the crosslinker, higher was the swelling resistance observed in microgel structure.

Amilopectina

Amilose

Nanoparticulas

Amido

Polimeros : Termodinamica

Starch polymers

Phase transition temperature

Microgel

N-isopropylacrylamide

Thermo-responsive polymer

Starch nanoparticles

Amylopectin

Amylose

Towards greener stationary phases : thermoresponsive and carbonaceous chromatographic supports

Tan, Irene

January 2011

Polymers which are sensitive towards external physical, chemical and electrical stimuli are termed as ‘intelligent materials’ and are widely used in medical and engineering applications. Presently, polymers which can undergo a physical change when heat is applied at a certain temperature (cloud point) in water are well-studied for this property in areas of separation chemistry, gene and drug delivery and as surface modifiers. One example of such a polymer is the poly (N-isopropylacrylamide) PNIPAAM, where it is dissolved well in water below 32 oC, while by increasing the temperature further leads to its precipitation. In this work, an alternative polymer poly (2-(2-methoxy ethoxy)ethyl methacrylate-co- oligo(ethylene glycol) methacrylate) (P(MEO2MA-co-OEGMA)) is studied due to its biocompatibility and the ability to vary its cloud points in water. When a layer of temperature responsive polymer was attached to a single continuous porous piece of silica-based material known as a monolith, the thermoresponsive characteristic was transferred to the column surfaces. The hybrid material was demonstrated to act as a simple temperature ‘switch’ in the separation of a mixture of five steroids under water. Different analytes were observed to be separated under varying column temperatures. Furthermore, more complex biochemical compounds such as proteins were also tested for separation. The importance of this work is attributed to separation processes utilizing environmentally friendly conditions, since harsh chemical environments conventionally used to resolve biocompounds could cause their biological activities to be rendered inactive. / Polymere, welche empfindlich gegenüber externen physikalischen, chemischen und elektrischen Einflüssen sind, werden „intelligente Materialien“ genannt. Diese werden weitverbreitet in medizinischen und technischen Anwendungen eingesetzt. Auf diesem Gebiet ausführlich erforschte Materialien sind Polymere, welche durch Hitze bei einer bestimmten Temperatur (Trübungspunkt) eine physikalische Veränderung eingehen können, genannt thermoresponsive Polymere. Eingesetzt werden diese z.B. in chromatographischen Trennverfahren, in Gen- und Wirkstofftransport Vorgängen und zur Oberflächenmodifikation. Ein Beispiel für so ein Polymer ist das poly(N-isopropylacrylamide) PNIPAAM, welches unter 32 °C in Wasser gelöst vorliegt und mit Erhöhung der Temperatur als Niederschlag ausfällt. In dieser Arbeit wurde ein alternatives Polymer, das poly(2-(2-methoxyethoxy)ethylmethacrylate-co-oligo(ethyleneglycol) methacrylate) (P(MEO2MA-co-OEGMA)), untersucht, in Bezug auf Biokompatibilität und der Änderung des Trübungspunktes in Wasser. Wenn eine Schicht eines temperaturempfindlichen Polymers auf einen Monolithen (einteiliger, poröser und auf Silika-basierendes Material) aufgebracht wird, werden die thermoresponsiven Eigenschaften auf die Oberfläche dieses Monolithen übertragen. Der Monolith dient hier als Säule in einer HPLC-Anlage. Es wurde gezeigt, dass das Hybrid-Material als einfacher „Temperaturschalter“ in der Trennung von fünf verschiedenen Steroiden in Wasser agieren kann. Untersucht wurde die Separation verschiedener Analyten mit dem Variieren der Säulentemperatur. Zusätzlich wurden mehr komplexe biochemische Stoffe, wie Proteine, getestet. Die Bedeutung dieser Arbeit ist zurückzuführen auf Separationsprozesse, welche umweltfreundlichen Bedingungen nutzen, da die rauen chemischen Bedingungen in konventionellen Separationsprozessen die biologische Inaktivität der Verbindungen zur Folge haben können. Der zweite Teil der Arbeit beschäftigte sich mit der Entwicklung eines alternativen Trägermaterials als Ersatz zu den Silika-basierende Trennungssäulen. Kohlenstoffmaterialien sind aufgrund ihrer ausgezeichneten mechanischen Härte und chemischen Stabilität eine vielversprechend Alternative. Die Synthese von Kohlenstoffkugeln als Trägermaterial kann als „grüner“ Prozess in meiner Arbeit angesehen werden, da milde Synthesebedingungen in purem Wasser verwendet wurden. Die Leistungsfähigkeit des Materials wurde mit einer Serie von Separationsreaktionen gezeigt.

thermoresponsive

poly(N-isopropylacrylamide)

oligo(ethyleneglycol)

Monolith

Chromatographie

thermoresponsive

poly(N-isopropyl acrylamide)

oligo(ethylene glycol)

monolith

chromatography

Chemistry and allied sciences

Microgéis termo-responsivos preparados a partir dos polímeros do amido

Leite, Daiani Canabarro

January 2017

Esta tese apresenta os estudos realizados quanto à síntese e caracterização de microgéis termo-responsivos de N-isopropilacrilamida (NIPAM) e macromoléculas de origem amilácea em sua composição, sistemas ainda pouco explorados na literatura. Inicialmente, nanopartículas de amido (SNP) foram preparadas por nanoprecipitação para incorporação nos microgéis de interesse, através da dissolução dos grânulos do amido em DMSO/H2O, aplicação de ultrassom e precipitação em não-solvente. As SNPs preparadas foram utilizadas como copolímero para formação de microgéis híbridos do tipo SNP-co-p(NIPAM) através de polimerização em emulsão na presença e na ausência de surfactante. A influência das SNPs nas propriedades dos microgéis foi estudada por MEV, DLS, PZ e SAXS, onde foram observadas mudanças no comportamento físico-químico e estrutura supramolecular dos microgéis. No geral, observaram-se deslocamentos da temperatura de transição de fase para valores maiores (até 35 °C, cerca de 3 °C acima do valor determinado para sistemas contendo p(NIPAM) puro), aumento da estabilidade coloidal e organização dos polímeros presentes no microgel em uma arquitetura caroço-casca. As propriedades de inchamento dos microgéis também foram estudadas através da teoria de Flory-Rehner, onde a temperatura theta e o grau de polimerização entre dois pontos de reticulação foram determinados através do ajuste apropriado do parâmetro de interação (χ). Paralelamente, visando um sistema diferente do descrito acima, foi estudado um novo agente de reticulação baseado nos polímeros do amido, a amilose e a amilopectina. Para isso, os polímeros do amido que compõem as nanopartículas foram modificados para a utilização como agente de reticulação na síntese de microgéis de p(NIPAM). Nesta etapa, uma reação de substituição dos grupos hidroxila dos polímeros do amido foi realizada com o cloreto de acriloíla de forma a inserir insaturações na estrutura dos polímeros, para que estes fossem aplicados como reticulante. O sucesso da reação de modificação foi verificado através de RMN 1H e FTIR, no qual um maior grau de substituição foi obtido quando um tempo maior de reação foi empregado. Microgéis de p(NIPAM) foram então preparados através de polimerização em emulsão utilizando os reticulantes sintetizados. Observou-se a influência do grau de substituição e da concentração do reticulante nos microgéis, analisados por MEV, DLS e UV-Vis com controle de temperatura. As principais mudanças foram relativas à temperatura de transição de fase e tamanho dos microgéis. Utilizando o agente de reticulação com maior grau de substituição, foi possível deslocar a temperatura de transição de fase dos microgéis preparados para valores maiores (35 °C, cerca de 3 °C acima do valor determinado para sistemas contendo p(NIPAM) puro). Observou-se também uma resposta mecânica da rede do microgel, que refletiu no tamanho das partículas, influenciada pela concentração dos agentes de reticulação e do grau de substituição. Quanto maior a concentração e o grau de substituição do agente de reticulação, maior a resistência ao intumescimento observado no microgel. / This thesis presents the studies regarding the synthesis and characterization of thermoresponsive microgels of N-isopropylacrylamide (NIPAM) and amylaceous-based macromolecules, which are systems still little explored in the literature. At first, starch nanoparticles (SNP) were prepared by nanoprecipitation, through dissolution of starch granules in DMSO/H2O, ultrasound application and non-solvent precipitation. SNPs were then used as copolymer in SNP-co-p(NIPAM) hybrid microgels synthesized by emulsion polymerization in the presence and absence of surfactant. The influence of SNPs in microgel properties were studied by SEM, DLS, ZP, and SAXS, where changes in the physicalchemical behavior and supramolecular structure were observed. Summing up, shifts in the phase transition temperature up to 35 °C, increased colloidal stability, and microgel polymers organization into a core-shell structure were observed. Microgels swelling behaviour were also studied by the Flory-Rehner theory, where the theta-temperature and the degree of polymerization between two crosslinker points were determined through interaction parameter (χ) fitting. In parallel, a new starch-based crosslinker was studied. For this purpose, starch polymers (amylose and amylopectin within the SNPs) were modified in order to use them as crosslinker in p(NIPAM) microgel synthesis. In this step, a substitution reaction in hydroxyl groups of SNP was carried out with acryloyl chloride, where double bonds were attached in polymers structure, making it suitable as a crosslinker. Reaction performances were evaluated through 1H NMR and FTIR. Then, p(NIPAM) microgels were prepared by emulsion polymerization using the crosslinker synthesized. The degree of substitution and the crosslinker concentration influence were verified and analyzed by SEM, DLS and UV-Vis with temperature control. The main observed changes were related to the phase transition temperature e microgels size. Using the crosslinker with higher substitution degree, it was possible the shift of the phase transition temperature to higher values (~35 °C). A mechanical response, observed trough microgels size, was found, driven by the crosslinker concentration and substitution degree. As higher the concentration and substitution degree of the crosslinker, higher was the swelling resistance observed in microgel structure.

Amilopectina

Amilose

Nanoparticulas

Amido

Polimeros : Termodinamica

Starch polymers

Phase transition temperature

Microgel

N-isopropylacrylamide

Thermo-responsive polymer

Starch nanoparticles

Amylopectin

Amylose

Microgéis termo-responsivos preparados a partir dos polímeros do amido

Leite, Daiani Canabarro

January 2017

Esta tese apresenta os estudos realizados quanto à síntese e caracterização de microgéis termo-responsivos de N-isopropilacrilamida (NIPAM) e macromoléculas de origem amilácea em sua composição, sistemas ainda pouco explorados na literatura. Inicialmente, nanopartículas de amido (SNP) foram preparadas por nanoprecipitação para incorporação nos microgéis de interesse, através da dissolução dos grânulos do amido em DMSO/H2O, aplicação de ultrassom e precipitação em não-solvente. As SNPs preparadas foram utilizadas como copolímero para formação de microgéis híbridos do tipo SNP-co-p(NIPAM) através de polimerização em emulsão na presença e na ausência de surfactante. A influência das SNPs nas propriedades dos microgéis foi estudada por MEV, DLS, PZ e SAXS, onde foram observadas mudanças no comportamento físico-químico e estrutura supramolecular dos microgéis. No geral, observaram-se deslocamentos da temperatura de transição de fase para valores maiores (até 35 °C, cerca de 3 °C acima do valor determinado para sistemas contendo p(NIPAM) puro), aumento da estabilidade coloidal e organização dos polímeros presentes no microgel em uma arquitetura caroço-casca. As propriedades de inchamento dos microgéis também foram estudadas através da teoria de Flory-Rehner, onde a temperatura theta e o grau de polimerização entre dois pontos de reticulação foram determinados através do ajuste apropriado do parâmetro de interação (χ). Paralelamente, visando um sistema diferente do descrito acima, foi estudado um novo agente de reticulação baseado nos polímeros do amido, a amilose e a amilopectina. Para isso, os polímeros do amido que compõem as nanopartículas foram modificados para a utilização como agente de reticulação na síntese de microgéis de p(NIPAM). Nesta etapa, uma reação de substituição dos grupos hidroxila dos polímeros do amido foi realizada com o cloreto de acriloíla de forma a inserir insaturações na estrutura dos polímeros, para que estes fossem aplicados como reticulante. O sucesso da reação de modificação foi verificado através de RMN 1H e FTIR, no qual um maior grau de substituição foi obtido quando um tempo maior de reação foi empregado. Microgéis de p(NIPAM) foram então preparados através de polimerização em emulsão utilizando os reticulantes sintetizados. Observou-se a influência do grau de substituição e da concentração do reticulante nos microgéis, analisados por MEV, DLS e UV-Vis com controle de temperatura. As principais mudanças foram relativas à temperatura de transição de fase e tamanho dos microgéis. Utilizando o agente de reticulação com maior grau de substituição, foi possível deslocar a temperatura de transição de fase dos microgéis preparados para valores maiores (35 °C, cerca de 3 °C acima do valor determinado para sistemas contendo p(NIPAM) puro). Observou-se também uma resposta mecânica da rede do microgel, que refletiu no tamanho das partículas, influenciada pela concentração dos agentes de reticulação e do grau de substituição. Quanto maior a concentração e o grau de substituição do agente de reticulação, maior a resistência ao intumescimento observado no microgel. / This thesis presents the studies regarding the synthesis and characterization of thermoresponsive microgels of N-isopropylacrylamide (NIPAM) and amylaceous-based macromolecules, which are systems still little explored in the literature. At first, starch nanoparticles (SNP) were prepared by nanoprecipitation, through dissolution of starch granules in DMSO/H2O, ultrasound application and non-solvent precipitation. SNPs were then used as copolymer in SNP-co-p(NIPAM) hybrid microgels synthesized by emulsion polymerization in the presence and absence of surfactant. The influence of SNPs in microgel properties were studied by SEM, DLS, ZP, and SAXS, where changes in the physicalchemical behavior and supramolecular structure were observed. Summing up, shifts in the phase transition temperature up to 35 °C, increased colloidal stability, and microgel polymers organization into a core-shell structure were observed. Microgels swelling behaviour were also studied by the Flory-Rehner theory, where the theta-temperature and the degree of polymerization between two crosslinker points were determined through interaction parameter (χ) fitting. In parallel, a new starch-based crosslinker was studied. For this purpose, starch polymers (amylose and amylopectin within the SNPs) were modified in order to use them as crosslinker in p(NIPAM) microgel synthesis. In this step, a substitution reaction in hydroxyl groups of SNP was carried out with acryloyl chloride, where double bonds were attached in polymers structure, making it suitable as a crosslinker. Reaction performances were evaluated through 1H NMR and FTIR. Then, p(NIPAM) microgels were prepared by emulsion polymerization using the crosslinker synthesized. The degree of substitution and the crosslinker concentration influence were verified and analyzed by SEM, DLS and UV-Vis with temperature control. The main observed changes were related to the phase transition temperature e microgels size. Using the crosslinker with higher substitution degree, it was possible the shift of the phase transition temperature to higher values (~35 °C). A mechanical response, observed trough microgels size, was found, driven by the crosslinker concentration and substitution degree. As higher the concentration and substitution degree of the crosslinker, higher was the swelling resistance observed in microgel structure.

Amilopectina

Amilose

Nanoparticulas

Amido

Polimeros : Termodinamica

Starch polymers

Phase transition temperature

Microgel

N-isopropylacrylamide

Thermo-responsive polymer

Starch nanoparticles

Amylopectin

Amylose

Novel Linear and Star Poly(vinylidene fluoride)-Based Polymers: Synthesis, Characterization and Applications

Algarni, Fatimah

24 November 2022

Poly(vinylidene fluoride) PVDF is a semi-crystalline fluoropolymer that attracted researchers' attention more than a decade ago due to its remarkable properties, such as mechanical strength, thermal stability, chemical resistance, good processability, and excellent aging resistance. Due to these excellent properties, PVDF is applied in many applications such as membranes and filtration, biomedical applications, drug delivery, batteries, energy generation, energy storage, sensors, actuators, and energy harvesting applications. The dissertation was inspired by PVDF’s outstanding properties and applications. First of all, the effect of chain topology of on the crystallization and polymorphism between linear and star PVDF homopolymers were studied. Well-defined linear and stars PVDF homopolymers architectures were synthesized by reversible addition−fragmentation chain transfer (RAFT) polymerization. The non-isothermal crystallization study showed an increase in the amount of ferroelectric β-phase with respect to the paraelectric α-phase as the number of arms in the PVDF stars increases. This finding is explained by the increased topological complexity in the stars of several arms, which leads to the preferential formation of the less thermodynamically stable ferroelectric β-phase. Moreover, the isothermal crystallization kinetics of the PVDF stars was faster than the linear PVDF as a result of their speedier nucleation. Secondly, we report the synthesis of poly(n-isopropylacrylamide)-b-poly(vinylidene fluoride) (PNIPAM-b-PVDF), amphiphilic block copolymers with linear and star architectures by RAFT sequential living polymerization. Due to the presence of a lower critical solution temperature (LCST) for PNIPAM (coil-globule transition around 32 °C), the synthesized PNIPAM-b-PVDF block copolymers have thermo-responsive behavior, therefore, potential application in the fabrication of thermo-responsive membranes. All fabricated membranes by nonsolvent-induced phase separation (NIPS) method exhibited thermo-responsive behavior with water permeability and PEG rejection experiments. Moreover, the several heating-cooling cycles showed that the thermal-responsive behavior of these membranes are reversible and stable. Finally, a suggested potential future work is given to synthesize other PVDF-based block copolymers via sequential living polymerizations.

polyvinylidene fluoride

RAFT polymerization

Radical polymerization

Linear and Star Architectures

crystallization kinetics

polymorphism

topology

poly(n-isopropylacrylamide)

thermo-responsive polymer

membrane applications.

Mechanical Conditioning of Cell Layers for Tissue Engineering

Lee, Elaine Linda

January 2011

No description available.

Biomedical Engineering

Biomedical Research

Engineering

Mechanical Engineering

Polymers

cardiomyocyte

myocardial infarction

poly (N-isopropylacrylamide)

tissue engineering

cell culture

mechanical conditioning

nondamaging

detachment

A Spin-Coated Thermoresponsive Substrate for Rapid Cell Sheet Detachment and Its Applications in Cardiac Tissue Engineering

Patel, Nikul Girishkumar

15 May 2014

No description available.

Biomedical Engineering

Biomedical Research

rapid cell sheet detachment

thermally responsive material

Poly N-isopropylacrylamide

pNIPAAm

aminopropyltriethoxysilane

APTES

human mesenchcymal stem cells

MSC

matrix metalloproteinase

MMP

fibrin

infarct

Synthesis, Characterization and Structure-Property Relationships of Polymer-Stabilized Nanoparticles Containing Imaging and Therapeutic Agents

Balasubramaniam, Sharavanan

06 February 2014

The controllable design of magnetic nanocarriers is essential for advanced in vivo applications such as magnetic resonance image-guided therapeutic delivery and alternating magnetic field-induced remote release of drugs. This work describes the fabrication of polymer-stabilized nanoparticles encapsulating imaging and therapeutic agents and delineates relationships among materials parameters and response. The effect of aggregation of magnetic iron oxide nanoparticles in aqueous suspension was characterized using a well-defined core-corona complex comprised of a superparamagnetic magnetite nanoparticle stabilized by terminally-anchored poly(N-isopropylacrylamide) (PNIPAM) corona. The modified Vagberg density distribution model was employed to verify that the complexes were individually dispersed prior to aggregation and was found to accurately predict the intensity-weighted hydrodynamic diameter in water. Aggregation of the complexes was systematically induced by heating the suspension above the lower critical solution temperature (LCST) of the polymer, and substantial increase in the NMR transverse relaxation rates was noted. Controlled clusters of primary iron oxide nanoparticles stabilized by the biodegradable block copolymer, poly(ethylene oxide-b-D,L-lactide) were fabricated by a scalable, rapid precipitation technique using a multi-inlet vortex mixer. Quantitative control over iron oxide loading, up to 40 wt%, was achieved. Correlations between particle parameters and transverse relaxivities were studied within the framework of the analytical models of transverse relaxivity. The experimental relaxivities typically agreed to within 15% with the values predicted using the analytical models and cluster size distributions derived from cryo-transmission electron microscopy. Hydrophilic-core particles assembled using the poly(ethylene oxide-b-acrylate) copolymer and at similar primary nanoparticle sizes and loadings had considerably higher transverse (r2) and longitudinal (r1) relaxivities, with r2s approaching the theoretical limit for ~ 8 nm magnetite. Block copolymer nanoparticles comprised of poly(D,L-lactide) and poly(butylene oxide) cores were utilized to encapsulate the poorly water-soluble antiretroviral drug, ritonavir, at therapeutically-useful loadings. Controlled size distributions were achieved by incorporation of homopolymer additives, poly(L-lactide) or poly(butylene oxide) during the nanoparticle preparation process. Nanoparticles either co-encapsulating a highly hydrophobic polyester poly(oxy-2,2,4,4-tetramethyl-1,3-cyclobutanediyloxy-1,4-cyclohexanedicarbonyl) within the core or possessing crosslinkable groups around the core were also successfully fabricated for potential sustained release of ritonavir from block copolymer carriers. / Ph. D.

magnetic nanoparticle

controlled clusters

relaxivity

MRI contrast

polylactide

poly(ethylene oxide)

poly(butylene oxide)

poly(N-isopropylacrylamide)

block copolymers

ritonavir

drug delivery

Caractérisation de la pharmacocinétique de formulations sensibles au pH et de formulations destinées au traitement des intoxications médicamenteuses

Bertrand, Nicolas

04 1900

La préparation de formulations à libération contrôlée est le domaine des sciences pharmaceutiques qui vise à modifier l’environnement immédiat des principes actifs pour en améliorer l’efficacité et l’innocuité. Cet objectif peut être atteint en modifiant la cinétique de circulation dans le sang ou la distribution dans l’organisme. Le but de ce projet de recherche était d’étudier le profil pharmacocinétique (PK) de différentes formulations liposomales. L’analyse PK, généralement employée pour représenter et prédire les concentrations plasmatiques des médicaments et de leurs métabolites, a été utilisée ici pour caractériser in vivo des formulations sensibles au pH servant à modifier la distribution intracellulaire de principes actifs ainsi que des liposomes destinés au traitement des intoxications médicamenteuses. Dans un premier temps, la PK d’un copolymère sensible au pH, à base de N-isopropylacrylamide (NIPAM) et d’acide méthacrylique (MAA) a été étudiée. Ce dernier, le p(NIPAM-co-MAA) est utilisé dans notre laboratoire pour la fabrication de liposomes sensibles au pH. L’étude de PK conduite sur les profils de concentrations sanguines de différents polymères a défini les caractéristiques influençant la circulation des macromolécules dans l’organisme. La taille des molécules, leur point de trouble ainsi que la présence d’un segment hydrophobe à l’extrémité des chaînes se sont avérés déterminants. Le seuil de filtration glomérulaire du polymère a été évalué à 32 000 g/mol. Finalement, l’analyse PK a permis de s’assurer que les complexes formés par la fixation du polymère à la surface des liposomes restaient stables dans le sang, après injection par voie intraveineuse. Ces données ont établi qu’il était possible de synthétiser un polymère pouvant être adéquatement éliminé par filtration rénale et que les liposomes sensibles au pH préparés avec celui-ci demeuraient intacts dans l’organisme. En second lieu, l’analyse PK a été utilisée dans le développement de liposomes possédant un gradient de pH transmembranaire pour le traitement des intoxications médicamenteuses. Une formulation a été développée et optimisée in vitro pour capturer un médicament modèle, le diltiazem (DTZ). La formulation liposomale s’est avérée 40 fois plus performante que les émulsions lipidiques utilisées en clinique. L’analyse PK des liposomes a permis de confirmer la stabilité de la formulation in vivo et d’analyser l’influence des liposomes sur la circulation plasmatique du DTZ et de son principal métabolite, le desacétyldiltiazem (DAD). Il a été démontré que les liposomes étaient capables de capturer et de séquestrer le principe actif dans la circulation sanguine lorsque celui-ci était administré, par la voie intraveineuse. L’injection des liposomes 2 minutes avant l’administration du DTZ augmentait significativement l’aire sous la courbe du DTZ et du DAD tout en diminuant leur clairance plasmatique et leur volume de distribution. L’effet de ces modifications PK sur l’activité pharmacologique du médicament a ensuite été évalué. Les liposomes ont diminué l’effet hypotenseur du principe actif administré en bolus ou en perfusion sur une période d’une heure. Au cours de ces travaux, l’analyse PK a servi à établir la preuve de concept que des liposomes possédant un gradient de pH transmembranaire pouvaient modifier la PK d’un médicament cardiovasculaire et en diminuer l’activité pharmacologique. Ces résultats serviront de base pour le développement de la formulation destinée au traitement des intoxications médicamenteuses. Ce travail souligne la pertinence d’utiliser l’analyse PK dans la mise au point de vecteurs pharmaceutiques destinés à des applications variées. À ce stade de développement, l’aspect prédictif de l’analyse n’a pas été exploité, mais le côté descriptif a permis de comparer adéquatement diverses formulations et de tirer des conclusions pertinentes quant à leur devenir dans l’organisme. / Drug delivery is the field of pharmaceutical sciences which focuses on altering the immediate environment of drug molecules to improve their efficacy and safety. Drug delivery systems can potentiate the effect of active principles or alleviate their side effects by modifying their circulation profiles and/or biodistribution. The objective of this research project was to investigate the role of pharmacokinetic (PK) analysis in the development of novel drug delivery systems. PK analysis is generally applied to describe and predict the blood concentration profiles of low molecular weight drugs and their metabolites. Nevertheless, it is herein used to characterize the circulation of 2 liposomal formulations: pH-sensitive liposomes designed to alter the intracellular distribution of drugs and liposomes with transmembrane pH gradient for drug detoxification. The first series of experiments were designed to study the circulation kinetics of a pH-sensitive polymer prepared with N-isopropylacrylamide (NIPAM) and methacrylic acid (MAA). The copolymer p(NIPAM-co-MAA) is used in our laboratory to prepare serum-stable, PEGylated, pH-sensitive liposomes. The circulation profiles of polymers with different characteristics were characterized. The parameters which impacted the fate of the macromolecules were the length of the polymer chain, its cloud point and the presence of a hydrophobic anchor at one extremity of the molecule. The glomerular filtration cut-off of the polymer was determined to be around 32,000 g/mol. PK analysis allowed to conclude that the complexes prepared by anchoring the polymer on the surface of the liposomes remained stable in the bloodstream. This data established that pH-sensitive vesicular formulations could be produced using a polymer which could be excreted through renal filtration. It also confirmed that the formulation remained intact in the bloodstream. The second part of this work involved the development of liposomes with a transmembrane pH gradient designed to treat cardiovascular drug intoxications. Liposomes were designed and optimized in vitro to capture a model cardiovascular drug, diltiazem (DTZ). In vitro, the liposome uptake capacity was 40-fold higher than the lipid emulsion used in the clinic. PK analysis was used to verify the stability of the formulation in vivo, and to assess the impact of the liposomes on the plasma concentration of DTZ and its principal active metabolite, deacetyl-diltiazem (DAD). It was shown that the vesicles were able to capture and sequester DTZ and DAD. Injection of liposomes 2 min prior to administration of DTZ significantly increased the area under the plasma-concentration vs. time curve of both DTZ and DAD, while lowering their clearance and volume of distribution. The impact of the changes in PK on the pharmacological effect of the drug was also investigated. Liposomes tempered the hypotensive effect of the drug when the latter was administered via an intravenous bolus or a 1-h perfusion. Throughout this work, PK analysis proved to be an efficient tool to study the ability of transmembrane pH gradient liposomes to alter the blood circulation profiles of a cardiovascular drug, and to reduce its pharmacological effect. This proof of concept establishes firm ground for the further development of this colloidal formulation to treat drug intoxications. This work pointed out the relevance of PK analysis for the development of multi-purpose, colloidal drug delivery systems. At this stage, the predictive nature of the analysis was not exploited, but its descriptive properties allowed objective comparison of the circulation profiles of distinct systems and pertinent conclusions concerning their fate in vivo.

liposomes

poly(éthylène glycol)

détoxication

émulsion lipidique

biodistribution

poly(N-isopropylacrylamide)

sensibilité au pH

chargement actif

pharmacocinétique

poly(ethylene glycol)

detoxification

lipid emulsion

pH-sensitivity

active loading

pharmacokinetic

biodistribution

poly(N-isopropylacrylamide)

liposomes